Gene product of v-fgr onc: hybrid protein containing a portion of actin and a tyrosine-specific protein kinase.

The nucleotide sequence of the region of Gardner-Rasheed feline sarcoma virus (GR-FeSV) encoding its primary translation product, p70gag-fgr, has been determined. From the nucleotide sequence, the amino acid sequence of this transforming protein was deduced. Computer analysis indicates that a portion of P70gag-fgr has extensive amino acid sequence homology with actin, a eukaryotic cytoskeletal protein. A second region of P70gag-fgr is closely related to the tyrosine-specific kinase gene family. Thus, the v-fgr oncogene appears to have arisen as a result of recombinational events involving two distinct cellular genes, one coding for a structural protein and the other for a protein kinase.

Transcription of c-onc genes c-rasKi and c-fms during mouse development.

We investigated the expression of cellular sequences c-rasKi and c-fms, which are homologous to the oncogenes of Kirsten rat sarcoma virus and the McDonough strain of feline sarcoma virus, during murine development and in a variety of mouse tissues. The c-rasKi gene was found to be transcribed into two mRNA species of approximately 2.0 and 4.4 kilobases, whereas a single c-fms-related transcript of approximately 3.7 kilobases was identified. The c-rasKi gene appeared to be expressed ubiquitously, since similar levels of transcripts were observed in embryos, fetuses, extraembryonal structures, and a variety of postnatal tissues. In contrast, significant expression of c-fms was found to be confined to the placenta and extraembryonal membranes (i.e., combined yolk sac and amnion). The concentration of c-fms transcripts in the placenta increased approximately 15-fold (relative to day-7 to day-9 conceptuses) during development before reaching a plateau at day 14 to 15 of gestation. The time course of cfms expression in the extraembryonal membranes appeared to parallel the stage-specific pattern observed in the placenta. The level of c-fms transcripts in the extraembryonal tissues reached a level which was approximately 20- to 50-fold greater than that in the fetus. These findings suggest that the c-fms gene product may play a role in differentiation of extraembryonal structures or in transport processes occurring in these tissues. Our results indicate that the c-onc genes analyzed in the present study exert essentially different functions during mouse development.

Human gene (c-fes) related to the onc sequences of Snyder-Theilen feline sarcoma virus.

The onc gene (v-fes) of the acutely transforming feline sarcoma virus (Snyder-Theilen strain) has homologous cellular sequences (c-fes) in all vertebrate species, including humans. We isolated from a human DNA library recombinant phages containing overlapping c-fes sequences. The human c-fes locus spans a region of 3.4 kilobases and contains 1.4 kilobases of DNA homologous to the viral onc sequence interspersed with three intervening sequences.

Characterization of the human c-fms gene product and its expression in cells of the monocyte-macrophage lineage.

The McDonough strain of feline sarcoma virus contains an oncogene called v-fms whose ultimate protein product (gp140v-fms) resembles a cell surface growth factor receptor. To identify and characterize the protein product of the proto-oncogene c-fms, antisera were prepared to the viral fms sequences and used to detect specific cross-reacting sequences in human choriocarcinoma cells (BeWo) known to express c-fms mRNA. Both tumor-bearing rat sera and a rabbit antiserum prepared to a segment of v-fms expressed in Escherichia coli detected a 140-kilodalton (kDa) glycoprotein in the BeWo cells. Tryptic fingerprint analysis of [35S]methionine-labeled proteins indicated that the viral fms proteins and the 140-kDa BeWo cell protein were highly related. This 140-kDa glycoprotein contained an associated tyrosine kinase activity in vitro and was labeled principally on serine after 32Pi metabolic labeling. These results suggest that the 140-kDa protein in BeWo cells is the protein product of the human c-fms proto-oncogene. This conclusion is supported by the finding that a similar protein is detectable only in other human cells that express c-fms mRNA. These other human cells include adherent monocytes and the cell line ML-1, which can be induced to differentiate along the monocyte-macrophage pathway. This is in agreement with current thought that the c-fms proto-oncogene product functions as the CSF-1 receptor specific to this pathway.

Analysis of functional domains of the v-fms-encoded protein of Susan McDonough strain feline sarcoma virus by linker insertion mutagenesis.

The Susan McDonough strain of feline sarcoma virus contains an oncogene, v-fms, which is capable of transforming fibroblasts in vitro. The mature protein product of the v-fms gene (gp140fms) is found on the surface of transformed cells; this glycoprotein has external, transmembrane, and cytoplasmic domains. To assess the functional role of these domains in transformation, we constructed a series of nine linker insertion mutations throughout the v-fms gene by using a dodecameric BamHI linker. The biological effects of these mutations on the function and intracellular localization of v-fms-encoded proteins were determined by transfecting the mutated DNA into Rat-2 cells. Most of the mutations within the external domain of the v-fms-encoded protein eliminated focus formation on Rat-2 cells; three of these mutations interfered with the glycosylation of the v-fms protein and interfered with formation of the mature gp140fms. One mutation in the external domain led to cell surface expression of v-fms protein even in the absence of complete glycosylational processing. Cell surface expression of mutated v-fms protein is probably necessary, but is not sufficient, for cell transformation since mutant v-fms protein was found on the surface of several nontransformed cell lines. Mutations that were introduced within the external domain had little effect on in vitro kinase activity, whereas mutations within the cytoplasmic domain all had strong inhibitory effects on this activity.

Early pre-B-cell transformation induced by the v-fms oncogene in long-term mouse bone marrow cultures.

Murine long-term bone marrow cultures that support B-lymphoid-cell development were infected with a helper-free retrovirus containing the v-fms oncogene. Infection of B-lymphoid cultures resulted in the rapid clonal outgrowth of early pre-B cells, which grew to high cell densities on stromal cell feeder layers, expressed v-fms-coded glycoproteins, and underwent immunoglobulin heavy-chain gene rearrangements. Late-passage cultures gave rise to factor-independent variants that proliferated in the absence of feeder layers, developed resistance to hydrocortisone, and became tumorigenic in syngeneic mice. The v-fms oncogene therefore recapitulates known effects of the v-abl and bcr-abl oncogenes on B-lineage cells. The ability of v-fms to induce transformation of early pre-B cells in vitro underscores the capacity of oncogenic mutants of the colony-stimulating factor-1 receptor to function outside the mononuclear phagocyte lineage.

Transformation by the v-fms oncogene product: role of glycosylational processing and cell surface expression.

The effect of glycosylational-processing inhibitors on the synthesis, cell surface expression, endocytosis, and transforming function of the v-fms oncogene protein (gp140fms) was examined in McDonough feline sarcoma virus-transformed Fischer rat embryo (SM-FRE) cells. Swainsonine (SW), a mannosidase II inhibitor, blocked complete processing, but an abnormal v-fms protein containing hybrid carbohydrate structures was expressed on the cell surface. SW-treated SM-FRE cells retained the transformed phenotype. In contrast, two glucosidase I inhibitors (castanospermine [CA] and N-methyl-1-deoxynojirimycin [MdN]) blocked carbohydrate remodeling at an early stage within the endoplasmic reticulum and prevented cell surface expression of v-fms proteins. CA-treated SM-FRE cells reverted to the normal phenotype. Neither SW, CA, nor MdN affected either endocytosis or the tyrosine kinase activity associated with the v-fms gene product in vitro. These results demonstrate the necessity of carbohydrate processing for cell surface expression of the v-fms gene product and illustrate the unique ability to modulate the transformed state of SM-FRE cells with the glycosylational-processing inhibitors CA and MdN.

The TP1 isolate of feline sarcoma virus encodes a fgr-related oncogene lacking gamma actin sequences.

We have isolated a new feline sarcoma virus, TP1-FeSV. The virus encodes a myristilated 83 kD gag-onc fusion protein displaying tyrosine kinase activity. We have established nonproducer cell lines lacking the TP1-FeSV associated helper virus (FeLV) and TP1-FeSV transfected NIH cell lines. Southern Blot analysis of genomic DNA and Northern Blot analysis of RNA isolated from these cell lines revealed that the oncogene of the TP1-FeSV isolate is related to the fgr oncogene of the GR-FeSV, but shows no hybridization to the gamma actin homologous sequences of the GR-FeSV. We have isolated TP1-FeSV specific clones from a genomic library. Restriction enzyme and sequence analysis showed that the TP1-FeSV genome consists of the first 1651 nucleotides of the gag gene, followed directly by fgr sequences. The TP1-FeSV fgr sequence starts 43 nucleotides after the beginning of the GR-FeSV fgr sequence. In contrast to the GR-FeSV fgr which has lost 13 amino acids of the c-fgr carboxy terminus, the TP1-FeSV fgr contains the complete carboxy terminus of the cellular fgr gene. The TP1-FeSV fgr sequence is followed by a unique 328 nucleotide long sequence of unknown origin. The 3' recombination site occurs within the pol gene, 460 nucleotides from the start of the env leader sequence. Comparison of the subcellular localization of the transforming proteins of TP1-FeSV and GR-FeSV show no striking difference; both molecules are in part associated with subcellular membrane/cytoskeletal fractions and form complexes with the cellular pp90 and pp50.

V-onc mutation associated with host cell growth in retroviral tumors.

In sarcomagenesis in rats infected neonatally with feline sarcoma virus (ST-FeSV), v-fes product (P85) was previously shown by us to be a predictive and preventive determinant. In order to explore the part played by P85 in tumor suppression, DNA was extracted from precancerous granulomas and from slow or rapid growing sarcomas induced by neonatal injection of the virus. The v-fes signal from extracted DNA was analyzed by PCR-SSCP. The prototype v-fes gene signal was detected in most lesions and found to be generally amplified in rapid growing sarcomas and in some granulomas. Several v-fes homologs showing varying mobilities in gel were seen in most sarcomas and some granulomas with or without the prototype v-fes signal. In slow growing sarcomas and granulomas induced in hosts that were immunized with ST-FeSV induced syngeneic sarcoma and proved to carry IgG antibody to P85, the prototype v-fes gene was found to be down-regulated and v-fes homologs were found to be reduced in number or eliminated. These results suggest that the development of v-fes mutations is associated with the growth potential of cells carrying the v-fes gene, and that host immunity to v-onc product influences the development of virogene rearrangements and results in slow and suppressed growth of tumors caused by neonatal infection with retrovirus.

Molecular cloning of the feline c-fes proto-oncogene and construction of a chimeric transforming gene.

The feline c-fes proto-oncogene, different parts of which were captured in feline leukemia virus (FeLV) to generate the transforming genes (v-fes) of the Gardner-Arnstein (GA) strain of feline sarcoma virus (FeSV) and the Snyder-Theilen strain (ST) of FeSV, was cloned and its genetic organization determined. Southern blot analysis revealed that the c-fes genetic sequences were distributed discontinuously and colinearly with the v-fes transforming gene over a DNA region of around 12.0 kb. Using cloned c-fes sequences, complementation of GA-FeSV transforming activity was studied. Upon replacement of the 3' half of v-fesGA with homologous feline c-fes sequences and transfection of the chimeric gene, morphological transformation was observed. Immunoprecipitation analysis of these transformed cells revealed expression of high Mr fusion proteins. Phosphorylation of these proteins was observed in an in vitro protein kinase assay, and tyrosine residues appeared to be involved as acceptor amino acid.

Structural analysis of a variant clone of Snyder-Theilen feline sarcoma virus.

A variant clone of Snyder-Theilen feline sarcoma virus (ST-FeSV) encoding a polyprotein with a molecular weight of approximately 104 kDa (P104) was compared to the P85 encoding prototype clone of ST-FeSV. Analysis of chimeric genes constructed with the viral oncogenes of the two clones indicated that the variant clone coded for a larger polyprotein than the prototype clone because of genetic differences in its 3' portion. Comparative DNA sequence analysis revealed that one nucleotide just upstream of the termination condon TGA in the prototype proviral DNA was deleted from the variant clone resulting in a 468-bp larger open reading frame. Furthermore, it appeared that the U3 regions of the long terminal repeats (LTRs) of the variant clone contained an insertion of 71 bp as compared to the LTRs of the prototype clone. In addition, both clones differed also from each other with respect to genetic sequences deleted from their env gene regions.

Human-fms gene is retained in acute lymphoblastic leukemia cells with del(5)(q32).

Cytogenetic and molecular investigations of NALM 6 cells (a pre-B-lymphoblastic acute leukemia cell line) revealed them to contain both alleles of the c-fms gene, though the cells had chromosomal changes of 5q- and 12p+. The amount of DNA fragments hybridized to the 1.4 kb PstI/PstI v-fms probe in the NALM 6 cells was approximately the same, when compared with cells of an Epstein-Barr virus-transformed lymphoblastoid cell line with a normal karyotype. Chromosome banding analysis revealed that the breakpoint of the 5q- in the NALM 6 cells was at the proximal portion of the 5q32 band. Chromosomal in situ hybridization of NALM 6 cells showed a significant accumulation of grains on the terminal portions of the abnormal 5q- chromosomes (5q32), as well as on the normal chromosomes #5 with a peak at 5q32-q33. These findings indicate that the human c-fms gene is not deleted in the lymphoblastic leukemia cells with a 5q- studied by us and that it does not show rearrangement or amplification. Thus, the results indicate that a difference in the dosage of the c-fms gene in acute lymphoblastic leukemia cells with the 5q- versus that in cells with the 5q- change in nonlymphocytic neoplasia; in the latter a hemizgosity of the c-fms gene has been suggested.

Conversion of human fibroblasts to tissue macrophages by the Snyder-Theilen feline sarcoma virus (ST:FeSV) is associated with the de-novo expression of IL-1 alpha, IL-1 beta, IFN-alpha, TNF-alpha, GM-CSF, and CD4.

In an earlier study, we have demonstrated the conversion of human fibroblasts (HF) to tissue macrophages (TM) by the Snyder-Theilen feline sarcoma virus (ST:(FeSV)) [1]. The present study shows that conversion of cultured HF by the ST:FeSV to TM resulted in the de-novo expression of interleukin-1 alpha, IL-1 beta, interferon-alpha, tumor necrosis factor-alpha, granulocyte-macrophage colony stimulating factor, and CD4. The conversion of HF to TM was also associated with increased expression of non-specific esterases as well as increased amount of ingested lipid material by the TM. Clonotypic and organotypic analyses of cells infected with the ST:FeSV(FeLV) showed a similar degree of conversion to TM among eleven individual clones of skin fibroblasts, and among fibroblasts obtained from eight different organs. These findings bear on the origin (heterogeneity) of TM, the nature of TM-induced cytokines, and the potential role of ST:FeSV-recruited TM during immune reactions in vivo.

Use of immunohistochemistry and polymerase chain reaction for detection of oncornaviruses in formalin-fixed, paraffin-embedded fibrosarcomas from cats.

OBJECTIVE: To determine whether there was intralesional infection or expression of FeLV or feline sarcoma virus in suspected vaccine-associated fibrosarcomas in cats. DESIGN: Prospective case series. SAMPLE POPULATION: 130 suspected vaccine-associated fibrosarcomas from cats and 1 multicentric fibrosarcoma from 1 cat. PROCEDURE: Excisional biopsy specimens were fixed in formalin and embedded in paraffin. Expression of FeLV antigen was assessed, using a polyclonal goat anti-FeLV glycoprotein 70 (gp 70) serum and an avidinbiotin immunoperoxidase staining technique. The FeLV genome was detected with a polymerase chain reaction (PCR), using primers targeted to a conserved sequence in the untranslated region of the long terminal repeat (LTR) of the FeLV. RESULTS: FeLV gp 70 and LTR sequence were detected in a multicentric fibrosarcoma. All 130 of the suspected vaccine-associated fibrosarcomas were FeLV gp 70 negative on the basis of immunohistochemical test results: 100 fibrosarcomas also were examined by use of PCR and were negative for FeLV LTR region. CLINICAL IMPLICATIONS: Exogenous retroviruses, FeLV, and feline sarcoma virus were not detected in these suspected vaccine-associated fibrosarcomas, using immunohistochemistry and PCR. Additional testing will be required to determine the nature of genomic alterations that are involved in the oncogenesis of vaccine-associated fibrosarcomas in cats.

Recombinant bacteriophages containing the integrated transforming provirus of Gardner--Arnstein feline sarcoma virus.

The integrated DNA provirus of the Gardner-Arnstein (GA) strain of feline sarcoma virus (FeSV) was molecularly cloned in a bacteriophage lambda vector. The cloned DNA fragment is 14.4 kilobase pairs long and contains a 6.7-kilobase provirus flanked by cellular sequences derived from nonproductively transformed mink cells. Transfection of mouse NIH/3T3 cells with the cloned DNA fragment induced foci of transformation at efficiencies of 10(4) focus-forming units/pmol of sarcoma virus DNA. Restriction endonuclease mapping and heteroduplex analyses were used to compare the GA-FeSV provirus with that of Snyder-Theilen (ST)-FeSV, a second strain that contains homologous transformation-specific sequences (v-fes). Both viruses have the general structure 5'-gag-fes-env-c region-3', each having retained portions of the feline leukemia virus (FeLV) gag and env genes. In addition to segments shared by the two sarcoma viruses, GA-FeSV contains 1.7 kilobases of extra sequences not found in ST-FeSV. Of these, at least 400-500 base pairs located near the 5' end of v-fes encode a portion of the GA-FeSV polyprotein; the remaining 1.2 kilobases are derived from the FeLV env gene but do not appear to encode any detectable product related to the FeLV envelope glycoprotein. The close homology of the v-fes sequences shows that GA- and ST-FeSV were formed by recombination of FeLV with similar portions of a cat cellular gene (c-fes).

Molecular cloning of the Fujinami sarcoma virus genome and its comparison with sequences of other related transforming viruses.

Full-length proviral DNA of Fujinami sarcoma virus (FSV) of chickens was molecularly cloned and characterized. An analysis of FSV DNA integrated in mammalian cells showed that restriction endonuclease SacI has a single cleavage site on FSV DNA. Unintegrated closed circular FSV DNA obtained from newly infected cells was linearized by digestion with SacI and cloned into lambdagtWES.lambdaB. The following three different molecules were isolated: FSV-1 (4.4 kilobases [kb]) and FSV-2 (4.7 kb), which appeared to be full-length FSV DNA molecules containing either one or two copies of the long terminal repeat structure, and FSV-3 (6 kb), which consisted of part FSV DNA and part DNA of unknown origin. An analysis of the structure of cloned FSV-1 and FSV-2 DNA molecules by restriction endonuclease mapping and hybridization with appropriate probes showed that about 2.6 kb of the FSV-unique sequence called FSV-fps is located in the middle of the FSV genome and is flanked by helper virus-derived sequences of about 1.3 kb at the 5' end and 0.5 kb at the 3' end. The long terminal repeats of FSV were found to have no cleavage site for either EcoRI or PvuI. Upon transfection, both FSV-1 DNA and FSV-2 DNA were able to transform mammalian fibroblasts. Four (32)P-labeled DNA fragments derived from different portions of the FSV-fps sequence were used for hybridization to viral RNAs. We found that sequences within the 3' half of the FSV-fps gene are homologous to RNAs of PRCII avian sarcoma virus and the Snyder-Theilen strain of feline sarcoma virus, both of which were previously shown to contain transforming genes related to FSV-fps. These results suggest that the 3' portion of the FSV-fps sequence may be crucial for the transforming activity of fps-related oncogenic sequences.

Three sizes of subunits in RNAs from feline sarcoma-leukaemia virus mixtures.

RNA from the Snyder-Theilen feline sarcoma-leukaemia virus complex (ST-FeSV-FeLV) sedimented in a double-peaked band between 50 and 70S, but Gardner-Arnstein (GA) FeSV-FeLV RNA sedimented in a single 70S peak. FeLV isolated from the ST virus mixture contained RNA which sedimented in a 70S band like GA-FeSV-FeLV RNA, but F422 FeLV RNA sedimented more slowly, at 50 to 60S. After thermal denaturation, resedimentation revealed three classes of RNA subunits in ST-FeSV-FeLV RNA: the first class, 35 to 37S, was also found in ST-FeLV and other FeLVs (except F422 FeLV), in the endogenous feline virus, RD114 and in GA-FeSV-FeLV; the second class, 32 to 34S, was similar to subunits in F422 FeLV and minor components of GA-FeSV-FeLV and ST-FeLV; the third class, 25S, was detected only in ST-FeSV-FeLV RNA. Electrophoresis of RNA species in buffered formamide provided evidence that the three classes of RNA subunits distinguishable on the basis of sedimentation rates actually represent three size classes of subunits. The ST virus mixture was shown to contain about equal titres of infectious FeLV and transforming FeSV whereas GA-FeSV-FeLV had at least a 10-fold excess fo FeLV over FeSV. These observations are discussed in terms of possible origins of the three sizes of FeSV-FeLV RNA subunits and their relationships to three species of FeSV-FeLV proviral DNA described recently (Sherr et al. 1979).

Cellular transformation by subgenomic feline sarcoma virus DNA.

The genome of the Snyder-Theilen strain of feline sarcoma virus (ST-FeSV) is a 4.3-kilobase-pair (kbp) RNA molecule that contains a 1.5-kbp cellular insertion (fes gene) flanked by feline leukemia virus sequences at its 5' end (1.6 kbp) and 3' end (1.2 kbp) (Sherr et al., J. Virol. 34:200-212, 1980). DNA transfection techniques have been utilized to determine the regions of the ST-FeSV genome involved in malignant transformation. I have found that the 3.7-kbp 5'-end fragment of the ST-FeSV provirus (which corresponds to the 3.4-kbp 5'-end fragment of the viral genome) is sufficient to transform NIH/3T3 fibroblasts. Enzymes that cleave the ST-FeSV provirus DNA within the feline leukemia virus gag gene sequences or within the fes gene abolished the transforming activity. Preservation of the proviral large terminal repeats was also required for transformation. Transformed NIH/3T3 cells obtained by transfection of total or subgenomic ST-FeSV DNA expressed normal levels of the ST-FeSV gene product ST P85 and of its associated protein kinase activity. Furthermore, these cells contained high levels of phosphotyrosine residues, a biochemical marker associated with cellular transformation induced by certain retroviruses including ST-FeSV. These results, taken together, strongly support the concept that only those ST-FeSV proviral sequences necessary for ST P85 expression are involved in malignant transformation.